U.S. patent application number 16/366432 was filed with the patent office on 2019-07-18 for beam generation optical system and image capturing apparatus provided with the same.
The applicant listed for this patent is FUJITSU FRONTECH LIMITED. Invention is credited to Isao IWAGUCHI, Kozo YAMAZAKI.
Application Number | 20190219803 16/366432 |
Document ID | / |
Family ID | 62024555 |
Filed Date | 2019-07-18 |
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United States Patent
Application |
20190219803 |
Kind Code |
A1 |
YAMAZAKI; Kozo ; et
al. |
July 18, 2019 |
BEAM GENERATION OPTICAL SYSTEM AND IMAGE CAPTURING APPARATUS
PROVIDED WITH THE SAME
Abstract
An optical element includes: a first transmissive section 3 that
causes light emitted from a light source to be incident on the
optical element; a first reflection section 4 which is located at a
facing section facing the first transmissive section and from which
light incident from the first transmissive section is reflected; a
second reflection section 5 which is located around the first
transmissive section and from which the light reflected from the
first reflection section is reflected; and a second transmissive
section 6 that causes the light reflected from the second
reflection section to be emitted out of the optical element in an
optical axis direction of the light source.
Inventors: |
YAMAZAKI; Kozo; (Inagi,
JP) ; IWAGUCHI; Isao; (Inagi, JP) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
FUJITSU FRONTECH LIMITED |
Tokyo |
|
JP |
|
|
Family ID: |
62024555 |
Appl. No.: |
16/366432 |
Filed: |
March 27, 2019 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
PCT/JP2016/082052 |
Oct 28, 2016 |
|
|
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16366432 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G01C 3/06 20130101; G02B
27/09 20130101; G02B 17/0868 20130101; G02B 19/0061 20130101; G02B
19/0028 20130101; G02B 17/086 20130101; G02B 27/0983 20130101; A61B
5/1171 20160201; G02B 5/10 20130101 |
International
Class: |
G02B 17/08 20060101
G02B017/08 |
Claims
1. A beam generation optical system that causes light emitted from
a light source to be incident on an optical element and causes the
incident light to be reflected and emitted out of the optical
element so as to generate a light beam, wherein the optical element
includes a first transmissive section that causes the light emitted
from the light source to be incident on the optical element, a
first reflection section which is located at a facing section
facing the first transmissive section and from which light incident
from the first transmissive section is reflected, a second
reflection section which is located around the first transmissive
section and from which the light reflected from the first
reflection section is reflected, and a second transmissive section
that causes the light reflected from the second reflection section
to be emitted out of the optical element in an optical axis
direction of the light source.
2. The beam generation optical system of claim 1, wherein the first
and second reflection sections each have a reflective film formed
thereon.
3. The beam generation optical system of claim 1, wherein the
optical element includes a plurality of members and are formed by
assembling the plurality of members.
4. The beam generation optical system of claim 3, wherein the
plurality of members are a member that includes the first
reflection section and the first transmissive section and a member
that includes the second reflection section and the second
transmissive section.
5. The beam generation optical system of claim 3, wherein the
plurality of members are a member that includes the first
reflection section and a member that includes the first
transmissive section and the second reflection section.
6. The beam generation optical system of claim 1, wherein the
second transmissive section forms a convex shape on an opposite
side from a light-source side.
7. The beam generation optical system of claim 1, wherein the first
reflection section forms a convex shape toward the light
source.
8. The beam generation optical system of claim 1, wherein the
second reflection section forms a convex shape on a light-source
side.
9. An image capturing apparatus comprising: a beam generation
optical system that causes light emitted from a light source to be
incident on an optical element and causes the incident light to be
reflected and emitted out of the optical element so as to generate
a light beam, wherein the optical element includes a first
transmissive section that causes the light emitted from the light
source to be incident on the optical element, a first reflection
section which is located at a facing section facing the first
transmissive section and from which light incident from the first
transmissive section is reflected, a second reflection section
which is located around the first transmissive section and from
which the light reflected from the first reflection section is
reflected, and a second transmissive section that causes the light
reflected from the second reflection section to be emitted out of
the optical element in an optical axis direction of the light
source.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation application of
International PCT Application No. PCT/JP2016/082052 which was filed
on Oct. 28, 2016.
BACKGROUND OF THE INVENTION
Field of the Invention
[0002] The present invention relates to a beam generation optical
system for generating a light beam, the beam generation optical
system emitting light from a light source via an optical
element.
Description of the Related Art
[0003] As illustrated in FIG. 11, a palm-vein-image capturing
apparatus irradiates a palm with ranging beams (also referred to as
light beams) emitted from ranging LED light sources disposed at
four corners (see FIGS. 12 and 13) and captures images of beam
spots (four spots with reference to this example) depicted in FIG.
15 resulting from the irradiation of the palm, thereby measuring a
distance. FIG. 12 illustrates the appearance of a conventional
image capturing apparatus. FIG. 13 illustrates a plane view of
illumination LED light sources and ranging LED light sources
depicted in FIG. 12. FIGS. 14A and 14B illustrate images indicating
beam spots captured by an image sensor.
[0004] The beam spots depicted in FIG. 14A are larger than those
depicted in FIG. 14B. This is because the image in FIG. 14A is an
image indicating beam spots captured when a subject such as a palm
is close to an image capturing apparatus, while the image in FIG.
14B is an image indicating beam spots captured when the subject is
distant from the image capturing apparatus. The height of each beam
spot on the subject and therefore an inclination of the subject can
be determined by measuring the distance between the center point
and each of the beam spots on the captured image.
[0005] An infrared LED, not a laser, is used as a light source in
view of the demand of small size and low cost. Unlike a laser, an
LED light source (also simply referred to as a light source) has a
chip surface that emits light, and hence the size of the light
source is limited. Accordingly, a beam spot for ranging that is
seen on a subject is essentially a spot provided by projecting the
shape of a light source chip, as depicted in FIG. 16.
[0006] FIGS. 17A-17C illustrate an example of a conventional
ranging-beam generation optical system (also referred to as a
ranging optical system or a beam generation optical system) to be
mounted on an image capturing apparatus. Near infrared light from a
light source passes through an aperture and is then emitted upward
by a lens (spherical lens). FIG. 17A depicts a basic configuration
for a ranging-beam generation optical system. To mount the
ranging-beam generation optical system on a palm-vein-image
capturing apparatus, an attaching member for the optical system may
be, as depicted in FIG. 17B, provided with an aperture and a lens
and attached to a printed board, or may be, as depicted in FIG.
17C, integrated with each of the four corners of a housing without
being in contact with the printed board.
[0007] FIGS. 18A and 18B illustrate examples of movements of light
lays (beam) of a beam generation optical system. More particularly,
FIGS. 18A and 18B each depict light rays on an XY plane, where the
XY plane is a plane on which a light source is placed, and Z
direction is a direction from the light source toward a subject.
This is also applicable to FIGS. 19A and 19B, which will be
described hereinafter, and to FIGS. 2A, 2B, 4A, and 4B, which will
be described with reference to embodiments.
[0008] In FIGS. 18A and 18B, a lens is distant from the light
source by 5 mm, and a beam is emitted upward from the lens. FIG.
18C depicts a beam spot distant from the light source by 100 mm,
while FIG. 18D depicts a beam spot distant from the light source by
10 mm. These beam spots are provided by projecting a square LED
chip using the lens.
[0009] Palm-vein-image capturing apparatuses are used in various
fields, including automated teller machines (ATMs) and entrance and
exit management apparatuses. In recent years, thin palm-vein-image
capturing apparatuses have been incorporated into note PCs and
tablet PCs (see, for example, Japanese Laid-open Patent Publication
No. 2008-36226). In accordance with the trend of making note PCs
and tablet PCs lighter and thinner, palm-vein-image capturing
apparatuses have been required to be thin. In order to achieve a
thin palm-vein-image capturing apparatus, it is important to make
thinner a ranging-beam generation optical system such as that
depicted in FIGS. 17A-17C, in addition to providing a thin imaging
system that includes an imaging lens and an image sensor.
[0010] In the example depicted in FIG. 18C, a beam spot with an
area of about 7 mm.times.7 mm is obtained on a screen distant from
the light source by 100 mm. In this example, the distance from the
light source to the lens is 5 mm. By contrast, FIGS. 19A-19D depict
characteristics achieved when the beam generation optical system is
made thinner by setting 2.5 mm as the distance from the light
source to the lens (i.e., 1/2 of the length in the example of FIG.
18A). A beam spot with an area of about 14 mm.times.14 mm (see FIG.
19C) is obtained on a screen distant from the light source by 100
mm, and a beam spot smaller than this cannot be obtained. Here, the
solid angle of the light rays which enters a lens to be utilized to
form a ranging beam are the same between FIGS. 18A and 19A.
[0011] FIGS. 20A and 20B illustrate relationships between beam spot
size and a distance between a light source and a lens. As described
above, a beam spot is actually obtained by projecting light from a
light source by using a lens. FIG. 20A depicts a situation in which
an image of an LED chip with edges each having a length of a is
enlarged at a ratio of H/h and projected onto an object as a square
with sides each having a length of A, where h indicates a distance
between the light source and the lens, and H indicates a distance
between the lens and the object.
[0012] However, when h/2 is set as the distance between the light
source and the lens as depicted in FIG. 20B in order to make the
optical system thinner, the ratio to the distance H to the object,
or the magnification of the image, is doubled, and hence the image
projected onto the object is a square with sides each having a
length of 2.times.A.
[0013] Doubling each side of a beam spot quadruplicates a beam spot
area, and hence the radiance is reduced to one-fourth when the
amount of emitted light (power) remains the same. This means that
the output is reduced to one-fourth because a beam spot image
obtained by the image sensor in the imaging system has a
proportional relationship with the radiance. Meanwhile, as the
distance becomes longer, the beam spot size is increased. This
causes a problem of a decreased degree of separation between four
beam spots on the palm. After all, making the optical system
thinner will decrease the sensitivity and accuracy of the ranging
function. Accordingly, the conventional beam generation optical
system has a trade-off between making the system thinner and
characteristics of ranging beams and can be made thinner only to a
limited degree.
[0014] To achieve a small beam spot, the lens and the light source
need to have a long distance therebetween to maintain a low
projection magnification, as depicted in FIG. 20A. However,
providing a long distance between the lens and the light source
hinders the providing of a thin image capturing apparatus, as
described above.
SUMMARY OF THE INVENTION
[0015] The present invention is directed to a beam generation
optical system that causes light emitted from a light source to be
incident on an optical element and causes the incident light to be
reflected and emitted out of the optical element so as to generate
a light beam, the optical element including: a first transmissive
section that causes the light emitted from the light source to be
incident on the optical element; a first reflection section which
is located at a facing section facing the first transmissive
section and from which light incident from the first transmissive
section is reflected; a second reflection section which is located
around the first transmissive section and from which the light
reflected from the first reflection section is reflected; and a
second transmissive section that causes the light reflected from
the second reflection section to be emitted out of the optical
element in an optical axis direction of the light source.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016] FIG. 1A is a side view of an optical element in accordance
with a first embodiment as seen from the side;
[0017] FIG. 1B is a plane view of an optical element in accordance
with a first embodiment as seen from above;
[0018] FIG. 2A illustrates an example of a movement of light rays
of a beam generation optical system that includes an optical
element in accordance with a first embodiment;
[0019] FIG. 2B illustrates an example of a movement of light rays
of a beam generation optical system that includes an optical
element in accordance with a first embodiment;
[0020] FIG. 2C illustrates a beam spot on a screen distant from a
light source of a beam generation optical system by 100 mm, the
beam generation optical system including an optical element in
accordance with a first embodiment;
[0021] FIG. 2D illustrates a beam spot on a screen distant from a
light source of a beam generation optical system by 10 mm, the beam
generation optical system including an optical element in
accordance with a first embodiment;
[0022] FIG. 3A is a side view of an optical element in accordance
with a second embodiment as seen from the side;
[0023] FIG. 3B is a plane view of an optical element in accordance
with a second embodiment as seen from above;
[0024] FIG. 4A illustrates an example of a movement of light rays
of a beam generation optical system that includes an optical
element in accordance with a second embodiment;
[0025] FIG. 4B illustrates an example of a movement of light rays
of a beam generation optical system that includes an optical
element in accordance with a second embodiment;
[0026] FIG. 4C illustrates a beam spot on a screen distant from a
light source of a beam generation optical system by 100 mm, the
beam generation optical system including an optical element in
accordance with a second embodiment;
[0027] FIG. 4D illustrates a beam spot on a screen distant from a
light source of a beam generation optical system by 10 mm, the beam
generation optical system including an optical element in
accordance with a second embodiment;
[0028] FIG. 5 illustrates that a second embodiment provides a beam
spot size that is smaller than that provided by a first
embodiment;
[0029] FIG. 6 illustrates advantageous effects of a second
embodiment;
[0030] FIG. 7 illustrates an example of the mounting of an optical
system in accordance with a second embodiment;
[0031] FIG. 8A is a perspective view of an optical element in
accordance with a third embodiment as seen obliquely from
above;
[0032] FIG. 8B is a side view of an optical element in accordance
with a third embodiment as seen from the side;
[0033] FIG. 9A is a perspective view of an optical element in
accordance with a fourth embodiment as seen obliquely from
above;
[0034] FIG. 9B is a side view of an optical element in accordance
with a fourth embodiment as seen from the side;
[0035] FIG. 10A illustrates other advantageous effects of the
invention;
[0036] FIG. 10B illustrates other advantageous effects of the
invention;
[0037] FIG. 11 illustrates how a palm is irradiated with a ranging
beam emitted from a ranging LED light source of a conventional
image capturing apparatus;
[0038] FIG. 12 illustrates an exemplary appearance of a
conventional image capturing apparatus;
[0039] FIG. 13 is a plane view of illumination LED light sources
and ranging LED light sources of a conventional image capturing
apparatus;
[0040] FIG. 14A illustrates an exemplary image indicating beam
spots that is captured by a conventional image capturing
apparatus;
[0041] FIG. 14B illustrates an exemplary image indicating beam
spots that is captured by a conventional image capturing
apparatus;
[0042] FIG. 15 illustrates beam spots provided by a conventional
image capturing apparatus;
[0043] FIG. 16 illustrates the shape of a beam spot provided by a
conventional image capturing apparatus;
[0044] FIG. 17A illustrates an example of the basic configuration
of a conventional beam generation optical system;
[0045] FIG. 17B illustrates an example of the mounting of a
conventional beam generation optical system;
[0046] FIG. 17C illustrates an example of the mounting of a
conventional beam generation optical system;
[0047] FIG. 18A illustrates an example of a movement of a light lay
of a conventional beam generation optical system;
[0048] FIG. 18B illustrates an example of a movement of a light lay
of a conventional beam generation optical system;
[0049] FIG. 18C illustrates beam spots provided on a screen by a
conventional beam generation optical system, the screen being
distant from a light source by 100 mm;
[0050] FIG. 18D illustrates a beam spot provided on a screen by a
conventional beam generation optical system, the screen being
distant from a light source by 10 mm;
[0051] FIG. 19A illustrates an example of a movement of light rays
provided by a conventional beam generation optical system when the
distance to the lens is 1/2 of the distance indicated in FIG.
18C;
[0052] FIG. 19B illustrates an example of a movement of light rays
provide by a conventional beam generation optical system when the
distance to the lens is 1/2 of the distance indicated in FIG.
18C;
[0053] FIG. 19C illustrates beam spots provided on a screen by a
conventional beam generation optical system when the distance to
the lens is 1/2 of the distance indicated in FIG. 18C, the screen
being distant from a light source by 100 mm;
[0054] FIG. 19D illustrates a beam spot provided on a screen by a
conventional beam generation optical system when the distance to
the lens is 1/2 of the distance indicated in FIG. 18C, the screen
being distant from a light source by 10 mm;
[0055] FIG. 20A illustrates, for a conventional beam generation
optical system, a relationship between beam spot size and a
distance h between a light source and a lens; and
[0056] FIG. 20B illustrates, for a conventional beam generation
optical system, a relationship between beam spot size and a
distance h/2 between a light source and a lens.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
First Embodiment
[0057] The following describes a first embodiment by referring to
drawings. The present invention features optical elements, and
non-optical-element components of an image capturing apparatus of
the invention that includes a beam generation optical system are
similar to those seen in the prior art. Accordingly, descriptions
of such non-optical-element components are omitted herein. This is
also applicable to the other embodiments described hereinafter. The
image capturing apparatus of the present invention, i.e., an image
capturing apparatus that includes a beam generation optical system,
does not need to be provided with an aperture, i.e., a component of
the conventional image capturing apparatus.
[0058] FIGS. 1A and 1B each depict the appearance of an optical
element in accordance with the first embodiment. FIG. 1A is a side
view of an optical element 1 as seen from the side. FIG. 1B is a
plane view of the optical element 1 as seen from above. As with the
conventional spherical lens, the optical element 1 depicted in
FIGS. 1A and 1B receives light emitted from a light source (LED)
2.
[0059] The optical element 1 includes, at a center of a
light-incidence side (light-source-2 side), a transmissive section
(first transmissive section) 3 through which light emitted from a
light source 2 enters the optical element 1. The optical element 1
also includes, at a center of a light-emission side (an opposite
side from the side on which the light source 2 is disposed), a
reflection section (first reflection section) 4 from which light
incident through the transmissive section 3 is reflected. The
transmissive section 3 and the reflection section 4 face each
other. The transmissive section 3 and the reflection section 4 as
seen from above have circular shapes as depicted in FIG. 1B, but
the shapes are not limited to this.
[0060] The optical element 1 also includes, around (at a portion
surrounding) the transmissive section 3, a reflection section
(second reflection section) 5 from which light reflected from the
reflection section 4 is reflected. The reflection section 5 forms a
convex shape on the light-source-2 side. The optical element 1 also
includes, around (at a portion surrounding) the first reflection
section 4, a transmissive section (second transmissive section) 6
through which light reflected from the reflection section 5 is
emitted out of the optical element 1 along an optical axis 7 toward
a subject (e.g., a palm) (not illustrated). The reflection section
5 and the transmissive section 6 face each other.
[0061] As described above, the optical element 1 is a lens that
forms a convex shape toward the light source 2 (downward convex
shape), as depicted in FIG. 1A. The lens of the optical element 1
maybe glass or may be another material, e.g., plastic. This is also
applicable to the materials for the optical elements in the other
embodiments described hereinafter. The transmissive section 3 and
the reflection section 4 each form a convex shape toward the light
source 2 but may each form a planar shape (flat surface).
[0062] Light emitted from the light source 2 enters the optical
element 1 through the transmissive section 3 of the optical element
1. While the region through which light enters (transmissive
section 3) is a lens surface, a reflective film is formed on the
outer surface of the optical element 1 so as to cover the
reflection section 5 located around (at a portion surrounding) the
transmissive section 3 (e.g., formed through meatal deposition such
as aluminum deposition). Similarly, a reflective film is formed on
the outer surface of the optical element 1 so as to cover the
reflection section 4. As a result, as in the case of the aperture
of the conventional ranging-beam generation optical system (beam
generation optical system), only light rays among the light rays
emitted from the light source 2 that forma predetermined angle with
the optical axis 7 are used to generate a beam, while the other
light rays are blocked by the refractive film of the reflection
section 5. The light that has entered the optical element 1 through
the transmissive section 3 is incident on the reflection section 4
provided over the transmissive section 3.
[0063] As described above, a reflective film is formed on the outer
surface of the optical element 1 so as to cover the reflection
section 4, and the reflection section 4 serves (functions) as a
convex .mirror for incident light. Accordingly, the reflection
section 4 reflects incident light toward the light incidence
surface (toward the light source 2) while enlarging the light. The
light that returns to the incidence-surface side after being
reflected is also reflected upward from the reflective film formed
on the outer surface of the optical element 1 so as to cover the
reflection section 5 and is then emitted through the transmissive
section 6 that faces the reflection section 5. The reflection
section 5, which serves as a concave mirror, emits light while
converging the light.
[0064] Light turns around upward and downward within the optical
element 1, as described above, and thus follows an extended light
path, and the light is then emitted toward a subject while
maintaining a low projection magnification effectively. As a
result, a beam spot on a screen distant from the light source 2 by
100 mm has, as depicted in FIG. 2C, a size of about 7.6
mm.times.7.6 mm, which is almost equal to the size indicated in
FIG. 18C. Meanwhile, FIG. 2D illustrates the size of a beam spot on
a screen distant from the light source 2 by 10 mm.
[0065] The beam generation optical system of the first embodiment
includes, as depicted in FIGS. 2A and 2B, an emission surface at a
position distant from the light source 2 by 3 mm, which is the same
as the position of the lens emission-surface that is depicted in
FIG. 19A. Accordingly, the beam spot size is almost the same as
that of a beam spot provided by the ranging-beam generation optical
system depicted in FIG. 18A, while the height is about 1/2 of that
of the ranging-beam generation optical system depicted in FIG. 18A,
i.e., the configuration is thinner. This means that the
configuration can be made thinner while the radiance of a spot for
which spot image outputs are to be determined remains the same.
Second Embodiment
[0066] The following describes a second embodiment by referring to
drawings. FIGS. 3A and 3B each depict the appearance of an optical
element in accordance with the second embodiment. FIG. 3A is a side
view of an optical element 21 as seen from the side. FIG. 3B is a
plane view of the optical element 21 as seen from above. As with
the optical element 1 in accordance with the first embodiment, the
optical element 21 depicted in FIGS. 3A and 3B receives light
emitted from a light source (LED) 2.
[0067] While the optical element 1 of the first embodiment includes
a base having a downward convex shape, the optical element 21 of
the second embodiment includes a base having convex shapes on both
sides, as depicted in FIG. 3A. In particular, a second reflection
section 25 forms a convex shape on the light-source-2 side, and a
second transmissive section 26 forms a convex shape on an opposite
side from the light-source-2 side.
[0068] The optical element 21 includes, at a center of a
light-incidence side (light-source-2 side), a transmissive section
(first transmissive section) 23 through which light emitted from
the light source 2 enters the optical element 21. The optical
element 21 also includes, at a center of a light-emission side (an
opposite side from the side on which the light source 2 is
disposed), a reflection section (first reflection section) 24 from
which light incident through the transmissive section 23 is
reflected. The transmissive section 23 and the reflection section
24 face each other. The transmissive section 23 and the reflection
section 24 as seen from above have circular shapes as depicted in
FIG. 3B, but the shapes are not limited to this. The transmissive
section 23 and the reflection section 24 each form a convex shape
toward the light source 2 but may each forma planar shape (flat
surface). This is also applicable to a third embodiment described
hereinafter.
[0069] The optical element 21 also includes, around (at a portion
surrounding) the transmissive section 23, a reflection section
(second reflection section) 25 from which light reflected from the
reflection section 24 is reflected. The reflection section 25 forms
a convex shape on the light-source-2 side. This is also applicable
to the third embodiment described hereinafter. The optical element
21 also includes, around (at a portion surrounding) the first
reflection section 24, a transmissive section (second transmissive
section) 26 through which light reflected from the reflection
section 25 is emitted out of the optical element 21 along an
optical axis 7 toward a subject (e.g., a palm) (not illustrated).
The reflection section 25 and the transmissive section 26 face each
other.
[0070] As in the first embodiment, a reflective film is formed on
the outer surface of the optical element 21 so as to cover the
reflection section 24 (e.g., formed through meatal deposition such
as aluminum deposition). A reflective film is also formed on the
outer surface of the optical element 21 so as to cover the
reflection section 25. The reflective surface of the reflective
film may be a metal-deposited surface or may be a refractive
surface formed by a multilayer film.
[0071] FIGS. 4A-4D depict examples of results of light-ray
simulations for a beam generation optical system using the optical
element 21 (reflecting optical system) of the second embodiment.
While the optical element 1 of the first embodiment includes, as a
base, a lens having a downward convex shape (a planer shape and a
convex shape on the upper side) , the optical element 21 of the
second embodiment includes a lens having convex shapes on both
sides. Accordingly, the curvature of the emission surface is
included in design parameters of the optical element 21, thereby
achieving a high design freedom. As a result, a beam spot size at a
position distant from the light source 2 by 100 mm is 6.7
mm.times.6.7 mm, as depicted in FIG. 4C. Meanwhile, FIG. 4D
indicates the size of a beam spot on a screen distant from the
light source 2 by 10 mm. As in the first embodiment, the beam
generation optical system of the second embodiment has, as depicted
in FIGS. 4A and 4B, an emission surface located at position distant
from the light source 2 by mm, which is the same as the position of
the lens emission-surface depicted in FIG. 19A.
[0072] The side length of the beam spot in accordance with the
second embodiment is 6.7 mm, although the side length of the beam
spot in accordance with the first embodiment is 7.6 mm. As
indicated in FIG. 5, the ratio of a side length is 88% and
therefore the ratio of the beam spot area is 78% between the second
embodiment and the first embodiment. Accordingly, the second
embodiment has the advantageous effect of achieving a smaller beam
spot.
[0073] The following quantitively describes the advantageous effect
of the second embodiment by comparing the second embodiment with
the prior art depicted in FIG. 19A. In addition to the conventional
path of light emitted from the light source 2 into and then out of
the lens, the configuration of the second embodiment includes the
feature wherein light is reflected from the center on the emission
side (first reflection section 24) and also reflected from the
reflective surface at the surrounding portion on the incidence side
(second reflection section 25), i.e., the light is reflected twice
(this is also applicable to the other embodiments). When light is
eventually emitted from the emission surface, the center of the
emission side (first reflection section 24) does not allow passage
of light rays, i.e., functions as an ineffective region.
[0074] Accordingly, in comparison with the prior art, the second
embodiment is accompanied by a power loss that corresponds to the
product of an effective area ratio and a reflection loss. On the
other hand, the second embodiment has the advantageous effect of
achieving a small beam spot area, i.e., achieving a high radiance
(illumination intensity). As depicted in FIG. 6, while the second
embodiment provides a transmissive power ratio of 0.7271 that is
the product of the effective area ratio and the reflection loss,
i.e., a lower value than in the prior art, the second embodiment
reduces the beam spot area to 1/4 and thus achieves a power density
of 4, thereby providing a radiance ratio (an essential advantageous
effect) of 2.91, i.e., the product of the transmissive power ratio
and the power density. Hence, a high radiance ratio is provided
even when the transmissive power ratio is low, so that a thin image
capturing apparatus can be achieved without decreasing the
sensitivity and accuracy of the ranging function.
[0075] FIG. 7 illustrates an example of the mounting of the optical
element 21 in accordance with the second embodiment. An attaching
part 71 for an optical element 21 (ranging optical system) is
integrated with each of four corners of a housing 70 of the image
capturing apparatus, and the optical element 21 is mounted onto the
attaching part 71. A cap 72 is fitted over and thus fixes the
optical element 21. A printed board 73 provided with the light
source 2 can be attached to the housing 70 without being in contact
with the attaching part 71. As long as passage of a light beam
traveling along an optical axis through the second transmissive
section 26 is not hindered, the cap 72 can have any size. In this
example, the cap 72 has a circular shape. However, as long as the
optical element 21 can be fixed and passage of a light beam is not
hindered, the shape of the cap 72 is not limited to a circular
shape. Note that optical elements in accordance with other
embodiments can be mounted in the same manner.
Third Embodiment
[0076] The following describes a third embodiment by referring to
drawings. In the embodiments described above, the optical element
includes a base having a downward convex shape (a planer shape and
a convex shape on the upper side) or a base having convex shapes on
both sides, and metal is deposited on portions of the optical
element so that these portions can function as reflective surfaces.
In the third embodiment and a fourth embodiment described
hereinafter, optical elements different from those described above
are used in consideration of manufacturability and costs.
[0077] FIGS. 8A and 8B each depict the appearance of an optical
element in accordance with the third embodiment. FIG. 8A is a
perspective view of an optical element 31 as seen obliquely from
above. FIG. 8B is a side view of the optical element 31 as seen
from the side. As with the optical element 21 in accordance with
the second embodiment, the optical element 31 depicted in FIGS. 8A
and 8B receives light emitted from a light source 2.
[0078] The optical element 31 of the third embodiment has a shape
similar to that of the optical element 21 of the second embodiment.
In the third embodiment, however, the optical element 31 includes a
plurality of members (two members with reference to this
embodiment); these members are assembled to function as the optical
element 31. In particular, the optical element 31 includes: a
member 80 that forms a convex mirror at a center of the optical
element 31; and a member 81 that includes a void at a center
thereof into which the member 80 is incorporated. The member 80 has
functions of the first transmissive section 23 and the first
reflection section 24 of the optical element 21 of the second
embodiment. The member 81 has functions of the second reflection
section 25 and the second transmissive section 26 of the optical
element 21 of the second embodiment.
[0079] In the third embodiment, an upper section 80a (first
reflection section 34) of the member 80 undergoes metal deposition,
and a second reflection section 35 of the member also undergoes
metal deposition. In combining the metal-deposited members, an
adhesive, e.g., a lens bond, is applied to an interface 82 between
the members 80 and 81. Thus, the members are bonded together to
form the optical element 31. The adhesive applied to the interface
82 has a refractive index equal to that of the members 80 and
81.
[0080] The members 80 and 81 are, for example, transparent plastic.
However, the material for the members 80 and 81 is not limit to
this.
Fourth Embodiment
[0081] The following describes a fourth embodiment by referring to
drawings. FIGS. 9A and 9B each depict the appearance of an optical
element in accordance with the fourth embodiment. FIG. 9A is a
perspective view of an optical element 41 as seen obliquely from
above. FIG. 9B is a side view of the optical element 41 as seen
from the side. As with the optical element 1 in accordance with the
first embodiment, the optical element 41 depicted in FIGS. 9A and
9B receives light emitted from a light source 2.
[0082] The optical element 41 of the fourth embodiment includes, as
in the third embodiment, a plurality of members (members 90 and 91)
but is not a lens base. The member 90 has functions of the first
reflection section 4 of the optical element 1 of the first
embodiment. The member 91 has functions of the first transmissive
section 3 and the second reflection section 5 of the optical
element 1 of the first embodiment. In the fourth embodiment, the
optical element 41 does not include the second transmissive section
6 described above with reference to the first embodiment but
includes an air space.
[0083] The member 90 includes a convex reflective mirror (convex
mirror) 90a and an attachment rib 90b. The convex reflective mirror
90a has formed thereon the reflective film of the other embodiments
described above. Accordingly, when the members 90 and 91 have been
combined, light incident through a light incidence section 91a of
the member 91 can be reflected while being expanded. The convex
reflective mirror 90a may correspond to the first reflection
section 4 of the first embodiment. The attachment rib 90b, which is
used to attach the member 90 to the member 91, is attached to
support parts 91b of the member 91 so as to form the optical
element 41.
[0084] The member 91 includes the light incidence section 91a
through which light from the light source 2 incident, the support
parts 91b for supporting the member 90, and a concave reflective
mirror (concave mirror) 91c. As with the first transmissive section
3 of the optical element 1 of the first embodiment, the light
incidence section 91a is located at a center of the concave
reflective mirror (concave mirror) 91c. The support parts 91b are
configured to support the member 90 by sandwiching the attachment
rib 90b, but the configuration of the support parts 91b is not
limited to this. The concave reflective mirror 91c has formed
thereon the reflective film of the other embodiments described
above. Thus, light reflected from the convex reflective mirror 90a
can be reflected along an optical axis toward a subject (not
illustrated). The concave reflective mirror 91c may correspond to
the second reflection section 5 of the first embodiment.
[0085] Such a configuration allows the power loss to be limited to
a low level since the inside of the optical element 41 is an air
space.
[0086] Next, descriptions will be given of other advantageous
effects of the invention by referring to FIGS. 10A and 10B. As
depicted in FIG. 10B, the conventional beam generation optical
system is such that when relative positions of a lens and a light
source 2 are not aligned, i.e., when the center of the light source
2 and the optical axis of the lens are offset from each other, the
same magnification as a beam spot is also applied to a misalignment
amount (e) of the beam spot. In particular, there has been a
problem that an accuracy in ranging is decreased if the
configuration is made thin since a beam spot position will be
excessively affected by misalignment between the light source 2 and
the lens. However, the present invention provides, as indicated
FIG. 10A, an optical path effectively equivalent to a path that
would be achieved by a combination lens, and the optical element on
the emission side serves (functions) to guide an outwardly
deviating light ray that occurs at an incidence section back to the
center. Hence, providing a thin configuration does not increase the
influence of lens misalignment on a beam position. It is another
advantageous effect of the present invention that a beam spot
position is not excessively affected by misalignment.
[0087] The beam generation optical system described above (an image
capturing apparatus that includes the beam generation optical
system) can prevent a spot radiance from being decreased while
maintaining a beam spot with a small size so that the image
capturing apparatus can be thin without decreasing the sensitivity
and accuracy of the ranging function. In addition, an image
capturing apparatus that includes the beam generation optical
system allows a ranging image of a beam spot on a palm to be
accurately obtained. Hence, for example, the ranging image and an
entire image of a subject such as a palm can be controlled and
obtained separately from each other, thereby providing high-quality
imaging data with no blurring.
EXPLANATIONS OF LETTERS OR NUMERALS
[0088] 1, 21, 31, 41: Optical element [0089] 2: Light source [0090]
3, 23: Transmissive section (First transmissive section) [0091] 4,
24: Reflection section (First reflection section) [0092] 5, 25:
Reflection section (Second reflection section) [0093] 6, 26:
Transmissive section (Second transmissive section) [0094] 7:
Optical axis [0095] 70: Housing [0096] 71: Attaching part [0097]
72: Cap [0098] 73: Printed board [0099] 80, 81, 90, 91: Member
[0100] 80a: Upper section [0101] 82: Interface [0102] 90a: Convex
reflective mirror [0103] 90b: Attachment rib [0104] 91a: Light
incidence section [0105] 91b: Support part [0106] 91c: Concave
reflective mirror
* * * * *